In a zero-phase current detecting apparatus, a feedback loop is made up of a pulse generating unit, a current detecting unit, a peak detecting unit, an adding unit, and a current regulating unit. The adding unit outputs a difference between a target value and a peak value detected by the peak detecting unit. A zero-phase current is detected based on the difference output from the adding unit as a result of regulation of the peak value so as to be the target value in the adding unit.
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1. A zero-phase current detecting apparatus comprising:
a zero-phase-sequence current transformer that includes a magnetic core and a detection coil wound around the core, and that detects a zero-phase current flowing in an electric power line; and
a feedback loop is made up of
a pulse generating unit that applies an excitation pulse signal to one end of the detection coil;
a current detecting unit that converts a current flowing through the detection coil into a voltage and outputs the voltage;
a peak detecting unit that detects a peak value of the voltage output from the current detecting unit;
an adding unit that outputs a difference between a target value and the peak value detected by the peak detecting unit; and
a current regulating unit that regulates the current flowing in the detection coil based on the difference output from the adding unit, wherein
the zero-phase current is detected based on the difference output from the adding unit as a result of regulation of the peak value so as to be the target value in the adding unit.
2. The zero-phase current detecting apparatus according to
3. The zero-phase current detecting apparatus according to
4. The zero-phase current detecting apparatus according to
5. The zero-phase current detecting apparatus according to
the zero-phase-sequence current transformer includes a secondary coil, and
the magnetization forcing unit controls the magnetization of the detection core by causing a current to flow through the secondary coil.
6. The zero-phase current detecting apparatus according to
7. The zero-phase current detecting apparatus according to
8. The zero-phase current detecting apparatus according to
9. The zero-phase current detecting apparatus according to
10. The zero-phase current detecting apparatus according to
11. The zero-phase current detecting apparatus according to
12. The zero-phase current detecting apparatus according to
13. The zero-phase current detecting apparatus according to
a time constant of the high-frequency passing unit is arranged to be equal to or longer than one second.
14. The zero-phase current detecting apparatus according to
when a zero point adjustment is performed upon an activation of the zero-phase current detecting apparatus, the time-constant changing unit temporarily makes the time constant smaller than the arranged value.
15. The zero-phase current detecting apparatus according to
16. The zero-phase current detecting apparatus according to
17. The zero-phase current detecting apparatus according to
18. The zero-phase current detecting apparatus according to
19. The zero-phase current detecting apparatus according to
20. The zero-phase current detecting apparatus according to
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The present invention generally relates to a zero-phase current detecting apparatus. The present invention specifically relates to a zero-phase current detecting apparatus in which a zero-phase-sequence current transformer is used.
A Zero-phase-sequence Current Transformer (ZCT) is a device that detects a zero-phase current flowing in an electric power line inserted through its own detection core. A ZCT is used, for example, in switchboards, electrical devices and the like, as a detector that detects a ground-fault current caused by a ground fault.
Patent Documents 1 and 2 are examples of documents that disclose a current detecting apparatus and the like in which a ZCT is used. For example, Patent Document 1 discloses a direct-current ground-fault detecting apparatus that detects a ground fault of a direct current at a low cost with a high level of precision thereby ensuring a high level of safety. Patent Document 2 discloses a direct-current ground-fault current detecting circuit that accurately detects whether a direct-current ground-fault current has generated or accurately detects a direct-current value at a given moment without being influenced by the hysteresis characteristics of a ZCT.
Patent Document 1: Japanese Patent Application Laid-open No. 2004-153991
Patent Document 2: Japanese Patent Application Laid-open No. 2005-065382
In the direct-current ground-fault detecting apparatus disclosed in Patent Document 1, a detection output from the ZCT is corrected based on a detection output from a temperature sensor that detects an atmospheric temperature near the ZCT. Accordingly, it is necessary to modify data used in the correction process depending on the type and the model of the ZCT being used and also to store, in advance, the data used in the correction process into a storage device such as a ROM. Consequently, this direct-current ground-fault detecting apparatus has a problem in that the mode of control for detecting a zero-phase current with a high level of precision becomes complicated, and the costs of designing and manufacturing the detecting apparatus become high.
In he direct-current ground-fault current detecting circuit disclosed in Patent Document 2, the detecting circuit detects a current that flows on the secondary side of the ZCT (the side on which a detection coil wound around a detection core included in the ZCT is positioned; hereinafter, “the secondary side”) by causing an offset current to flow on the primary side of the ZCT (the side on which the electric power line inserted through the detection core is positioned; hereinafter, “the primary side”). In this configuration, however, an output gain for the detection current detected in the detection coil on the secondary side varies, depending on the amount of the offset current that is caused to flow on the primary side. Thus, there is a problem in the direct-current ground-fault current detecting circuit disclosed in Patent Document 2 that the level of precision in the detection process for the zero-phase current degrades.
This invention has been made in view of the above. It is an object of the present invention to provide a zero-phase current detecting apparatus in which a ZCT is used and that makes it possible to prevent degradation in the level of precision in the detection process without increasing the costs.
To solve the above problems and achieve the objects, a zero-phase current detecting apparatus comprising a zero-phase-sequence current transformer that includes a detection coil and is operable to detect, via the detection coil, a zero-phase current flowing in an electric power line inserted through the zero-phase-sequence current transformer, includes a pulse generating unit that applies an excitation pulse signal to one end of the detection coil included in the zero-phase-sequence current transformer; a current detecting unit that is connected to other end of the detection coil and converts a current flowing via the detection coil into a voltage output; a peak detecting unit that detects a peak value of the output voltage output from the current detecting unit; an adding unit that outputs a difference value between a predetermined target value and the peak value; and a current regulating unit that regulates the current flowing in the detection coil based on an output of the adding unit, wherein a feedback loop is made up of the current detecting unit, the peak detecting unit, the adding unit, and the current regulating unit, and the zero-phase current is detected based on the output of the adding unit obtained when an output of the peak detecting unit is regulated so as to be the target value under the control of the feedback loop.
In the zero-phase current detecting apparatus according to the present invention, a feedback loop is made up of the current detecting unit, the peak detecting unit, the adding unit, and the current regulating unit. A zero-phase current is detected based on an output of the adding unit obtained when an output of the peak detecting unit is regulated so as to be equal to the target value under the control of the feedback loop. Thus, an advantageous effect is achieved where it is possible to provide a zero-phase current detecting apparatus that makes it possible to prevent degradation in the level of precision in the detection process without increasing the costs.
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ZCT: zero-phase-sequence current transformer
Exemplary embodiments of a zero-phase current detecting apparatus according to the present invention will be explained in detail with reference to the accompanying drawings. It should be noted that the present invention is not limited to these exemplary embodiments.
Next, a connection configuration of the zero-phase current detecting apparatus shown in
Next, the operation of the zero-phase current detecting apparatus according to the first embodiment will be explained, with reference to
In
The output of the peak detecting circuit 15a is input to one of input terminals (i.e., the reversal input terminal) of the proportional integral controller 21. A target value γ set by the target value output circuit 25a is input to the other of the input terminals (i.e., the non-reversal input terminal) of the proportional integral controller 21. The proportional integral controller 21 performs a proportional integral computation by using the difference between the target value γ and the output of the peak detecting circuit 15a as an input signal. A proportional integral output is input to the current detector 12a.
Next, the function of the current detector 12a will be explained. As explained above, the current detector 12a converts the current flowing in the detection coil 14 into a voltage and outputs the voltage. In other words, the current detector 12a has the function to detect the current flowing in the zero-phase-sequence current transformer ZCT. On the other hand, if we take a look at the connection of the resistor 12b that is included in the current detector 12a, the output of the proportional integral controller 21 is connected to a terminal (a second end) of the resistor 12b that is different from a connection terminal (a first end) being connected to the detection coil 14 included in the zero-phase-sequence current transformer ZCT. Because of this connection state, the output of the proportional integral controller 21 has an action to change the electric potential of the second end side of the resistor 12b that is used as a reference for the output of the current detector 12a (i.e., the output to the peak detecting circuit 15a). It is also acceptable to consider that this action is caused by a decrease in the voltage detected by the current detector 12a because a current that corresponds to the output of the proportional integral controller 21 flows toward the pulse generator 11a via the detection coil 14. In any case, the current detector 12a also has the current regulating function to regulate the current flowing in the detection coil 14, as shown in the functional diagram in
Returning to the description of
The state in this situation is shown in
From the situation shown in
Next, the voltage output from the current detector 12a, i.e., the voltage output from the present apparatus will be explained. First, when no zero-phase current is flowing in the electric power line 10, the output waveform of the current detector 12a changes according to the excitation pulse signal generated by the pulse generator 11a in the manner shown in the lower half of
Next, the current value (corresponding to I0 above) that is caused to flow in the detection coil 14 in advance will be explained.
According to the first embodiment, the proportional integral controller 21 shown in
On the other hand, if a large zero-phase current flows in this situation, the current that flows in the current detecting unit 12 (i.e., the detection coil 14) is reversed, as shown in
Generally speaking, a situation rarely occurs in which the operation is out of the control range because of a large zero-phase current. However, if a large zero-phase current should flow by any chance, there is a possibility that the operation goes out of the control range assumed by the zero-phase current detecting apparatus according to the present invention.
To cope with this problem, according to the second embodiment, the control polarity reversal preventing unit 30 is provided between the adding unit 18 and the current regulating unit 20.
In
To cope with this problem, according to the third embodiment, the magnetization forcing unit 32 that acts on the current detecting unit 12 or the detection coil 14 is provided, as explained above.
In
As shown in
It is acceptable to configure the magnetization instruction generator 32b by using a controller other than a microcomputer. It should be noted, however, that by configuring the magnetization instruction generator 32b by using a microcomputer, it is possible to exercise control in a finely-tuned manner with regard to magnetization instructions (e.g. magnetization periods and magnetization timing) and the like. Thus, it is possible to detect the current with an even higher level of precision.
In the configuration described above, the magnetizing current I1 that is caused to flow in the detection coil 14 is regulated via the magnetization forcing circuit 32a; however, another arrangement is also acceptable in which a secondary coil (i.e., a magnetization control coil) that is different from the detection coil 14 is provided so that the magnetizing current I1 is caused to flow in the magnetization control coil.
Yet another arrangement is also acceptable in which a control line that is different from the electric power line 10 is inserted through the detection core included in the zero-phase-sequence current transformer ZCT so that the magnetizing current is caused to flow in the control line. temporarily
When a method that employs the detection coil or a secondary coil such as the magnetization control coil is used, the current level proportional to the ratio of the number of turns of the coil is considered to be equivalent to the level of a current flowing through the detection core included in the zero-phase-sequence current transformer ZCT. Thus, it is possible to make the current used in the magnetization control smaller.
Also, when a method that employs such a secondary coil is used, if an exclusive-use coil such as the magnetization control coil is employed, it is possible to exercise control simultaneously and independently so that the output voltage of the peak detecting circuit is stabilized, and also the magnetized state of the detection core included in the zero-phase-sequence current transformer ZCT is stabilized. Thus, it is possible to maintain the ease with which the control is exercised. Consequently, it is possible to exercise control with an even higher level of precision.
On the other hand, when a method that employs such a secondary coil is used, if the detection coil is employed, it is possible to use a general-purpose zero-phase-sequence current transformer ZCT. Thus, it is possible to configure the zero-phase current detecting apparatus at a low cost.
In addition, when the method in which a current is caused to flow on the primary side of the zero-phase-sequence current transformer ZCT is used, it is also possible to use a general-purpose zero-phase-sequence current transformer ZCT. Thus, it is possible to configure the zero-phase current detecting apparatus at a low cost.
Next, a zero-phase current detecting apparatus according to a fourth embodiment of the present invention will be explained. The zero-phase current detecting apparatus according to the fourth embodiment is characterized in that it provides a control method to maintain detection performances with an even higher level of precision by appropriately controlling the magnetizing current applied to the detection core included in the zero-phase-sequence current transformer ZCT so as to prevent the detection core included in the zero-phase-sequence current transformer ZCT from becoming saturated. The zero-phase current detecting apparatus according to the fourth embodiment may have a configuration similar to that of the zero-phase current detecting apparatus according to the third embodiment.
Based on the configuration of the zero-phase current detecting apparatus according to the third embodiment, let us discuss a situation in which a magnetizing current is forcibly caused to flow in a predetermined coil so that the magnetized state of the detection core included in the zero-phase-sequence current transformer ZCT can be controlled. In this situation, the detection core included in the zero-phase-sequence current transformer ZCT may become saturated, depending on the current amount of the magnetizing current that is forcibly caused to flow. In such a situation, it is difficult to detect a zero-phase current. Accordingly, to prevent the detection core included in the zero-phase-sequence current transformer ZCT from becoming saturated, it is necessary to control the current amount of the magnetizing current so as to be at an appropriate level.
For example, it is desirable to continuously perform an operation to cause a magnetizing pulse current to flow (hereinafter, “magnetizing operation”) for a short period of time. By exercising control this way, it is possible to prevent the detection core included in the zero-phase-sequence current transformer ZCT from becoming saturated and to perform the detection process with an even higher level of precision.
Also, when the magnetizing operation is continuously performed for a short period of time as described above, it is desirable to cause the magnetizing pulse current to flow in synchronization with an excitation pulse. When the magnetizing pulse current is not in synchronization with an excitation pulse, the state of the magnetic flux of the detection core included in the zero-phase-sequence current transformer ZCT during a cycle period in which the magnetizing operation is performed is different from the state of the magnetic flux during a cycle period in which no magnetizing operation is performed. Thus, the output of the peak detecting circuit is not stable. However, if the magnetizing operation is performed in synchronization with the excitation pulse, it is possible to stabilize the operation of the peak detecting circuit.
Accordingly, by performing the magnetizing operation one or more times in every excitation cycle period, it is possible to exercise control so that the magnetized state of the detection core included in the zero-phase-sequence current transformer ZCT maintains the predetermined state. Thus, it is possible to maintain a stable magnetized state.
It is preferable to have an arrangement so that the length of the period in which the magnetizing operation is performed for a short period of time is equal to or shorter than 20% of the excitation cycle period (more preferably, equal to or shorter than 5% of the excitation cycle period) and also so that one output is made in every excitation cycle period. With this arrangement, it is possible to prevent the detection core included in the zero-phase-sequence current transformer ZCT from becoming saturated and to perform the detection process with an even higher level of precision.
For example, as shown in
On the other hand, the changes in the detection output of the zero-phase-sequence current transformer ZCT are determined by a time constant for the changes in the ambient temperature. The time constant is sufficiently larger than a time required to perform the zero-phase current detection. Thus, it is possible to perform a filtering process by using the high frequency passing unit 34. By performing the filtering process, it is possible to limit the influence from the changes in the ambient temperature and to perform the zero-phase current detection process with a high level of precision.
When the time constant of the high frequency passing unit 34 is arranged to be a short period of time, there is a higher possibility that a change in the output caused by detection of a zero-phase current and a change in the output caused by a change in the ambient temperature are erroneously detected. To cope with this problem, it is desirable to have an arrangement in which the time constant of the high frequency passing unit 34 is, for example, equal to or longer than 10 seconds. By having the arrangement in which the time constant of the high frequency passing unit 34 is equal to or longer than 10 seconds, it is possible to detect a component that has a frequency equal to or higher than 0.016 hertz (Hz), out of the detection output of the peak detecting unit. Thus, it is possible to inhibit influence from the changes in the ambient temperature and to perform the detection process with a high level of precision.
Also, depending on the degree with which the ambient temperature changes (the difference when the environment is good and when the environment is bad), another arrangement is acceptable in which the time constant of the high frequency passing unit 34 is, for example, equal to or longer than 1 minute, or equal to or longer than 20 minutes. By having the arrangement in which the value of the time constant is changed, as necessary, depending on the usage environment, it is possible to reduce the amount of undetected components related to the zero-phase current. It is also possible to lower the possibility of erroneous detection caused by the changes in the ambient temperature.
Like the magnetization forcing unit 32 according to the third embodiment, it is possible to configure the high frequency passing unit 34 by using a microcomputer. When the high frequency passing unit 34 is configured by using a microcomputer, there is no need to provide a filtering circuit. Thus, it is possible to perform the detection process with a high level of precision at a low cost.
In the description of the fifth embodiment, the example has been explained in which the configuration including the high frequency passing unit 34 provided between the adding unit 18 and the output terminal 26 is applied to the zero-phase current detecting apparatus according to the first embodiment shown in
In the description of the fifth embodiment, the example has been explained in which the time constant of the high frequency passing unit 34 is arranged to be, for example, equal to or longer than 10 seconds, so that it is possible to detect the component that has a frequency equal to or higher than 0.016 hertz, out of the detection output of the peak detecting unit.
On the other hand, to detect a zero-phase current, it is necessary to adjust a zero point (i.e., to perform an offset calibration) so that an output obtained when no zero-phase current is flowing is zero.
When the filtered output of the high frequency passing unit 34 is expressed as V(t), it is possible to express V(t) by using Equation (1):
V(t)=(1−e−(t/T))*V0 (1)
where t=detection period, T=time constant, and V0=regulated target voltage
As understood from Equation (1), when the time constant is large, it takes a longer period of time to adjust the zero point.
To cope with this problem, in the zero-phase current detecting apparatus according to the sixth embodiment, when the offset calibration process is performed, the time constant changing unit 36 temporarily changes the time constant of the high frequency passing unit 34 (i.e., makes it smaller). By performing the time constant changing control this way, it is possible to shorten the period of time required to adjust the zero point.
If the time constant used when the zero point adjustment is performed is changed to 1 second, and the calibration period is 4 seconds, it is possible to obtain the following Equation from Equation (1):
V(4)=(1−e−(4/1))*V0≅0.98V0
It means that it is possible to make a fluctuation in the zero point adjustment equal to or lower than 2%, with a calibration period of 4 seconds.
In the description of the sixth embodiment, the example has been explained in which the configuration including the time constant changing unit 36 is applied to the zero-phase current detecting apparatus according to the fifth embodiment shown in
Next, a zero-phase current detecting apparatus according to a seventh embodiment of the present invention will be explained. The zero-phase current detecting apparatus according to the seventh embodiment is characterized in that it provides a control method to maintain detection performances with an even higher level of precision by preventing a ripple component related to an excitation frequency of the excitation pulse from being present in a detection output. The zero-phase current detecting apparatus according to the seventh embodiment may have a configuration similar to that of the zero-phase current detecting apparatus according to any one of the first to the sixth embodiment.
For example, in the zero-phase current detecting apparatus according to the first embodiment, an arrangement is made so that discrete values are each obtained from a predetermined phase every time (i.e., the phase is the same every time) in synchronization with the excitation cycle period of the excitation pulse, as shown in
Next, a zero-phase current detecting apparatus according to an eighth embodiment of the present invention will be explained. The zero-phase current detecting apparatus according to the eighth embodiment is characterized in that, after a detection output is obtained as discrete values by using a sampling interval having a cycle period shorter than a half of the excitation cycle period (i.e., the frequency is two or more times higher), an excitation frequency component is eliminated by performing a digital signal processing. The zero-phase current detecting apparatus according to the eighth embodiment may have a configuration similar to that of the zero-phase current detecting apparatus according to any one of the first to the seventh embodiments.
For example, by using the zero-phase current detecting apparatus according to the first embodiment, a sampling is performed on the detection output while the sampling frequency is set to be 4.7 kilohertz (kHz), when the excitation frequency of the excitation pulse is 2 kilohertz. After that, a filtering process is performed on a sampled output, based on the digital filter shown in
As shown in
As explained above, in the zero-phase current detecting apparatus according to the first embodiment, the feedback loop is made up of the current detecting unit, the peak detecting unit, the adding unit, and the current regulating unit. The output of the peak detecting unit is regulated so as to be the target value by the control of the feedback loop. A zero-phase current flowing in the zero-phase-sequence current transformer is detected based on the output of the adding unit obtained when the output of the peak detecting unit is regulated so as to be equal to the target value. Thus, it is possible to have the detection characteristic of the peak detecting unit positioned in a linear area having linearity. Thus, it is possible to achieve a high level of precision in the detection process. In addition, there is no need to choose a special detector to maintain the level of precision in the detection process. Thus, it is possible to configure a zero-phase current detecting apparatus having a high level of precision in the detection process at a low cost.
Also, in the zero-phase current detecting apparatus according to the second embodiment, the control polarity reversal preventing unit provided between the output of the adding unit and the input of the current regulating unit operates so as to prevent the operating point of the peak detecting unit from reversing. Thus, even if a large current flows, the operating point of the peak detecting unit does not go out of the control range. Thus, it is possible to maintain a high level of precision in the detection process.
Further, in the zero-phase current detecting apparatus according to the third embodiment, the magnetization forcing unit controls the magnetized state of the detection core included in the zero-phase-sequence current transformer. Thus, the detection core included in the zero-phase-sequence current transformer maintains the predetermined magnetized state. Thus, it is possible to detect the current with a high level of precision, without receiving any influence from external magnetizing factors.
Furthermore, in the zero-phase current detecting apparatus according to the fourth embodiment, the magnetization forcing unit repeatedly and continuously performs the magnetizing operation that lasts for a shorter period of time than the excitation cycle period of the excitation pulse output by the pulse generating unit, once in every regular or non-regular cycle period of the excitation pulse. Thus, it is possible to maintain a stable magnetized state. Accordingly, it is possible to perform the detection process with a high level of precision.
Also, in the zero-phase current detecting apparatus according to the fifth embodiment, the time constant of the high frequency passing unit that passes the high frequency component in the output of the adding unit is arranged to be equal to or longer than one second. Thus, it is possible to detect a component that has a frequency equal to or higher than 0.016 hertz, out of the detection output of the peak detecting unit. Consequently, it is possible to inhibit the influence from the changes in the ambient temperature and to perform the detection process with a high level of precision.
Further, in the zero-phase current detecting apparatus according to the sixth embodiment, when a zero point adjustment is performed upon an activation of the zero-phase current detecting apparatus, the time constant changing unit that is operable to change the time constant of the high frequency passing unit temporarily makes the time constant smaller than the arranged value used during the operation. Thus, it is possible to shorten the period of time required to perform the zero adjustment.
Furthermore, in the zero-phase current detecting apparatus according to the seventh embodiment, the digital processor that has the function of the high frequency passing unit outputs, as discrete values, sampled values out of the output of the adding unit that are obtained in synchronization with the excitation cycle period of the excitation pulse. Thus, it is possible to effectively suppress the ripple component contained in the detection output. Consequently, it is possible to maintain a high level of precision in the detection process.
Also, in the zero-phase current detecting apparatus according to the eighth embodiment, when outputting the sampled values out of the output of the adding unit as the discrete values, the digital processor that has the function of the high frequency passing unit obtains the sampled values by using a cycle period shorter than a half of the excitation cycle period of the excitation pulse and also eliminates the excitation frequency component of the excitation pulse contained in the discrete values by performing a digital signal processing. Thus, it is possible to effectively suppress the ripple component contained in the detection output. Consequently, it is possible to maintain an even higher level of precision in the detection process.
It is possible to use the zero-phase current detecting apparatus according to any one of the first to the eighth embodiments as, for example, a ground-fault detecting circuit for a grid-connected inverter apparatus. In particular, the grid-connected inverter apparatus may be an inverter apparatus for a photovoltaic power generation system. It is more useful to apply the zero-phase current detecting apparatus according to the present invention to such a photovoltaic power generation system that has gotten a lot of attention as a clean energy source against the backdrop of recent increases in environmental problems on a world-wide scale.
As explained above, the zero-phase current detecting apparatus according to the present invention is useful for application to, for example, a ground-fault detecting circuit for a grid-connected inverter apparatus.
Tajima, Daisuke, Nishio, Naoki, Nakabayashi, Hirokazu
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